DE3917214A1 - Method for the bit-serial transmission of datawords - Google Patents

Abstract

The bit-serial data transmission method assigns binary datawords (C1, C2, ..., Cn) in a channel code to binary datawords (D1, D2, ..., Dn) of an output code before transmission in a transmission channel. This data transmission method is to be distinguished by a high transmission efficiency. This is achieved by the datawords (D1, D2, ..., Dn) of the output code exhibiting an octet structure and a dataword with twelve binary characters of the channel code being assigned to each dataword of the output code. Each dataword of the channel code also exhibits six equal binary characters and six binary characters which are inverse thereto. The binary character sequence in each dataword (C1, C2, ..., Cn) of the channel code is also selected in such a manner that in the bit-serial succession of datawords (C1, C2, ..., Cn) of a message (10), three identical binary characters at the most occur next to one another. In addition, the channel code is selected in such a manner that certain binary character sequences (SZB, SZE) provided for the message synchronisation do not occur in arbitrary sequences of datawords (C1, C2, ..., Cn) of the channel code. <IMAGE>

Description

TECHNICAL AREA

The invention is based on a method according to the first part of claim 1.

STATE OF THE ART

Here, the invention relates to a prior art, as described in MIL-STD-1553 (USAF) "Aircraft Internal Time Command / Response Multiplex Data Bus Division " is. In the method according to the prior art bit serial transmission of binary coded information channel codes used, which allow a clock recovery in the receiver. Depending on the logical value, each binary character becomes a positive one or a negative step change of two successive assigned different binary signals of the channel code (Manchester II code). For synchronization characters are used for Differentiation of information signs with at least sequences defined three identical steps. This allows the information to be transmitted simply from the clock of the night  recovery systems and is also a comparative one effective detection of channel code errors also in the Ensure interference from the transmission channel accomplishes. However, the transfer rate is only 0.5 da per binary character of the output code two binary characters in the channel code must be transferred.

PRESENTATION OF THE INVENTION

The invention as defined in claim 1 solves the task of a method for bit serial transmission of data to indicate which is with effective detection of disturbances and at the same time advantageous feasibility due to good transmission efficiency with a transmission rate greater than 0.5.

In the method according to the invention, the transmission effi efficiency for user data compared to a process that Manchester II code used, increased 4: 3. Because it is largely insensitive to interference given flows and also a simple execution of the process due to easy recovery of the transmitted user data from the beat of the underlying messaging system is achieved with the inventive method great transmission security compared to comparable processes saves significant costs.

WAYS OF CARRYING OUT THE INVENTION

The invention is described below with reference to a drawing illustrated embodiment explained in more detail. Here demonstrate:

Fig. 1 is a block diagram of the data source side part and

Fig. 2 is a block diagram of the data sink part of an electrical communication system in which the inventive method is carried out.

Data words D ₁ , D ₂ ,... Are located in the part of the electrical communication system on the data source side shown in FIG. 1. . ., D _n in a transmission data memory 1 . A binary output code of octet structure is assigned to these data words. A maximum of 256 different data words D ₁ , D ₂ ,. . ., D _n occur. Furthermore, there are binary-coded synchronization characters SZ _B, ..., S Z _E in a synchronization character memory 2 . In an assignment memory 3 , which is preferably designed as a read-only memory, 256 data words of a channel code, each with twelve binary characters, each with six identical binary characters and six binary characters inverse thereto, for example 010001011011 or 010001011101, are stored in ascending order. One of 256 addresses is assigned to each data word of the channel code.

A transmission control logic 4 can directly access the synchronization memory 2 and via an address control 5 on the transmission data memory 1 and the allocation memory 3 . The characters read out of the synchronization memory 2 and the allocation memory 3 are fed via address-controlled AND functions 6 , 7 , the outputs of which are connected to an OR function 8 , to a parallel-series converter 9 in which a bit-serial telegram 10 is formed . At the beginning, this telegram contains a synchronization character S Z _B , which is read out by the transmission control logic 4 from the synchronization memory 2 and via the AND function 6 , which is activated by the transmission control logic 4 , and the OR function 8, the parallel series. Converter 9 has been supplied. The telegram also contains data words C ₁ , C ₂ , ... C _{n of} the channel code. These data words are formed by the transmit control logic 4, the data words provided in the transmission data storage 1 D _1, D _2, reads _n D sequentially ..., each data word read via the address controller 5 as an address, for example 2, leading to the assignment memory 3 and thereby each Read out data word D ₁ , D ₂ , ..., D _{n of} the output code assigns exactly one data word C ₁ , C _2, ..., C _{n of} the channel code, which is activated via the AND simultaneously activated by the transmission control logic 4 or the address control 5 -Function 7 and the OR function 8 to the parallel series converter 9 has been performed.

The data words D ₁ , D ₂ ..., D _{n of} the binary output code therefore act as address pointers pointing to an encryption point stored in the assignment memory 3 and their twelve-digit data words C ₁ , ..., C _n assigned by the address pointer of the channel code now instead of the eight-digit data words D ₁ , ..., D _{n of} the output code are transmitted bit-serially in a transmission channel arranged between the data source and the data sink and consisting, for example, of two wires. Due to the suitable choice of the channel code, each data word C ₁ , C ₂ ..., C _{n of} the channel code contains the same number of binary characters with the logical value "1" and the logical value "0". This and the additional requirement that the binary character string in each data word of the channel code is selected such that in the case of bit-serial succession of data words C ₁ , C ₂ ..., C _n of telegram 10, at most three identical binary characters occur next to one another in the transmission channel, DC-free transmission of telegram 10 is ensured. At the same time, a largely memory-free transmission, ie a transmission in which the transmission signals of a group of binary characters do not depend on previously transmitted groups of binary characters, is guaranteed, and a comparatively high transmission rate of 2: 3 is also achieved.

The data words of the encryption table are also selected so that in the telegram 10 any successive data words C ₁ , C ₂ ..., C _{n of} the channel code are free of predetermined binary character strings with at least six binary characters and a maximum of three identical binary characters occurring next to each other. Such binary character strings can then be transmitted as synchronization characters for identifying the start S Z _B and / or end S B _{E of} the telegram 10 or for identifying the type of a further telegram before and / or after the data words of the channel code. A suitable synchronization word is advantageously provided by a binary character string in which three identical binary characters and three binary characters inverse to one another appear next to one another, such as the binary character sequence 111000. Table 1 given in the appendix shows a list of the data words of the channel code sorted according to increasing binary values for the 256 binary data words of the output code. Obviously, the channel code shown in Table 1 avoids the binary string 111000 used as a synchronization character in any sequence of its tabulated data words.

A method for bit-serial transmission of data based on such an encryption table is sufficient for many message transmission systems. In certain electrical message systems, however, two or more synchronization characters are required, which clearly differ from the data words of the channel code, be it to indicate the beginning or end of a telegram or to alternate types of telegrams (questions / answers, organization telegrams / information telegrams) to distinguish distinguishable start synchronization characters. For these requirements, binary character strings of the form XX .. XX 01110001 XX .. XX (with X = 0 or 1) can be defined as synchronization characters, with the binary character string 111000 being able to occur repeatedly in a synchronization character.

For reasons of efficiency, synchronization characters should be possible be as short as possible. Two easily distinguishable, short synchronies Stationary characters advantageously have eight binary characters each on which of the first two synchronization characters two inverse to each other next to three consecutive same ones Binary characters occur, such as with the binary string 11100010. In the case of a second of both synchronous characters, they are  Binary characters compared to the first synchronization character inverted, so that then, for example, the binary string 00011101 occurs. Table 2 shown in the Appendix shows a listing of the ascending binary values Channel code data words for the 256 binary data words of the output code. The channel code avoids any Sequence of his tabulated data words the binary sequences 11100010 and 00011101. These two binary characters can therefore be followed as easily distinguishable start and Use end characters of a telegram, but can also be used as different start characters are used.

The two synchronization characters 11100010 and 00011101 used as different starting characters, is their Suitability on channel codes with RZ (return to zero) signals limits. For channel codes with NRZ (non return to zero) sig creating two different starting characters is recommended each of the two syn Assign ten binary characters to chronological characters. At a The first two synchronization characters are followed by three of the same and three inverse binary characters to each other and occur two mutually inverse binary characters next to the three same and the three inverse to it, such as in the Characters 0100011101. On a second of both synchronization Signs are the three of a kind that appear side by side and the three inverse binary characters to the first Synchronization characters are inverted and are the remaining ones four binary signs the beginning and end of the syn Chronization characters assigned such that the first and second Synchronization characters each with the same binary character start and end. Has such a synchronization sign then about the following appearance 0101110001. The attached Table 3 shows a channel code, which is in Ver use of the two synchronization characters 0101110001 and 0100011101 suitable for NRZ signals.  

In the data sink-side part of the electrical communication system shown in FIG. 2, the data of the telegram 10 received after the transmission in the transmission channel (not shown) are first processed bit-serially. First, the binary characters assigned to the synchronization character S Z _B are checked in a synchronization character decoder 11 . Here, the received signals via a tuned to the clock frequency of the communication system PLL demodulator 12 (phase-locked loop demodulator 12 ) and two AND functions 13 , 14 are fed to an input of the synchronization character decoder 11 . If the synchronization character decoder 11, which is controlled by a receive control logic 15 via the PLL demodulator 12, recognizes the synchronization character S Z _B , then the signals of the data words C ₁ , C ₂ ..., C _n des processed in the PLL demodulator 12 arrive received frame 10 via the enabled AND radio from the receive control logic 15 functions 13, 14 to a code checker 16, in which it is determined whether the received data word of the selected encryption table fulfills the conditions of the channel code to the invention. If this condition is not met, a code error transmitter 17 reports this to the user at an interface 19 via an AND function 18 activated by the reception control logic 15 . Otherwise, the data word C ₁ , C ₂ ,..., C _{n of} the channel code recognized as correct is via an AND function 20 which is inverted by the code error generator 17 , a series / parallel converter 21 controlled by the reception control logic 15 and one of the Receive control logic 15 controlled address control 22 led as an address pointer to a memory 23 designed as a read-only memory.

In this assignment memory 23 of the supplied data words C _1, C ₂ ... C of the channel code _n actuated (and for the sake of clarity, in decimal notation shown) addresses preferably twelve-digit binary words, but may be also readily eleven-digit binary words.

This is due to the fact that the last received binary character of a data word of the channel code enables a parity check of the previously received 11 binary characters and is therefore no longer required after the code error check for a unique assignment of one of the 256 data words of the output code. The data words of the output code are stored as eight-digit binary words, for example 00000000, 00000001, in the assignment memory 23 in ascending order. If a data word C ₁ ..., C _{n of} the channel code transmitted by the telegram 10 now points to an address of the assignment memory as an address pointer, then exactly one eight-digit data word assigned to this address, for example D ₁ , is read from the assignment memory 23 and via one of the address control 22 activated AND function 24 entered in a receive data memory 25 and transferred to the user at the interface 19 via an AND function 26 activated by the receive control logic 15 .

Claims (6)

1. A method for bit-serial transmission of data words ( D ₁ , D ₂ ..., D _n ) of a binary output code from a data source via a transmission channel to a data sink, in which the data words ( D ₁ , D ₂ ..., D _n ) before transmission, a binary channel code with a transmission rate less than one is assigned, characterized in that the data words of the output code have an octet structure, and that each data word of the output code is divided into a data word having twelve binary characters ( C ₁ , C ₂ ... , C _n ) of the channel code with six identical binary characters and six inverse binary characters is converted, the binary string in each data word ( C ₁ , C ₂ ..., C _n ) of the channel code being selected such that in the case of bit-serial succession of data words ( C ₁ , C ₂ ..., C _n ) of a telegram ( 10 ) transmitted in the transmission channel, at most three identical binary characters appear next to one another. 2. The method according to claim 1, characterized in that in the telegram ( 10 ) any consecutive data words ( C ₁ , ₂ ..., C _n ) of the channel code are free of predetermined binary strings with at least six binary characters and a maximum of three coexisting glei Chen binary characters, and that these predetermined binary characters follow as synchronization characters for identifying the beginning and / or end of the telegram ( 10 ) or for identifying the type of another telegram before and / or after the data words ( C ₁ , C ₂ ..., C _n ) the channel code are transmitted in the transmission channel. 3. The method according to claim 2, characterized in that to form a first synchronization character ( S Z _B ) occur in a first of the predetermined binary strings three identical binary characters and three inverse binary characters side by side. 4. The method according to claim 3, characterized in that the first binary character string (... X 01110001 Y ...) before the three identical binary characters by one inverse to these binary characters and before the inverse binary character by at least a first further binary character ( X ) is added, and after the three inverse binary characters by one inverse to the inverse binary characters and after this by at least a second further binary character ( Y ), and that to form the first and a second synchronization character ( S Z _E ) mutually inverse values of the first ( X ) and the second additional binary character ( Y ) can be selected. 5. The method according to claim 3, characterized in that at least eight binary characters are assigned to the first synchronization character ( S Z _B ), two of which occur inverse to one another in addition to three successive identical binary characters, and that a second synchronization character ( S Z _E ) is formed by a sequence of characters that is inverse to the first binary character. 6. The method according to claim 3, characterized in that at least ten binary characters are assigned to the first synchronization character, of which two mutually inverse binary characters occur in addition to the three identical binary characters and the three inverse binary characters (0100011101), and in that a second synchronization character ( S Z _E ) is also formed with at least 10 binary characters by inversion of the six binary characters, each with three identical characters occurring next to one another, and assignment of the remaining at least four binary characters to the beginning and the end of the second synchronization character ( S Z _E ) to be formed, that the first and second synchronization characters ( S Z _B , S Z _F ) start and end with the same binary characters (0101110001).